Gyration balancing calibration free high-speed boring tool

ABSTRACT

A gyration balancing calibration free high-speed boring tool allowing fast interchanging between different bore sizes includes an adapter and a boring bar body; a micro-eccentric bore on the adapter to accommodate a pivoting shaft; a V-shaped ring groove being disposed to the pivoting shaft; a securing and a locating threaded holes being provided on the adapter; an eccentric locating recess being provided to each threaded hole; a securing screw being each disposed to a locating pin and an elastic locating screw for foolproof purpose; the boring bar body being tightly contact with the adapter firmly secured to the adapter to provide excellent rigidity.

BACKGROUND OF THE INVENTION

(a) Field of the Invention

The present invention is related to a high-speed boring tool, and more particularly to one that is free of gyration balancing calibration in working on changed bore size and contains a foolproof securing structure allowing fast interchange in inching the bore size.

(b) Description of the Prior Art

Referring to FIG. 19 of the accompanying drawings showing a boring tool 10 with bore size adjustable of the prior art, an adjusting screw drives a screw lock 12 and an adapter 13 to change the position of the tip of a disposable insert 14 in adjusting the bore size. However, once the position of the adapter 13 is changed, the gyration balancing of the bore tool must be readjusted to avoid creating a bore of false circle during the boring operation at high revolving speed. Readjustment of the gyration balancing is achieved by means of a gyration balancing weight structure including another adjusting screw 15 and a weight 16. The position of the weight 16 is adjusted and placed on a gyration-balancing machine for calibration. While the readjusting process usually is time consuming, more time is needed due to the increased frequency of inspection of the true circle of the product, thus higher production cost. Some manufacturers try to reduce the tolerance of false circle at a lower revolving speed (approximately 2000 rpm); but the reduced tolerance is made at the expenses of slower process speed, greater surface roughness, and reduced surface gloss.

As illustrated in FIGS. 16, 17, and 18 respectively showing a perspective view and two sectional views of application Ser. No. 10/680,061, there is no directional limitation whatsoever designed either in the engagement between a securing threaded hole 23′ and a limiting block 231′ or in the engagement between a locating threaded hole 24′ and an elastic locating block 241′ for an adapter 20′; instead, possible confusion between the limiting block 231′ and the elastic locating block 241′ is prevented only by making the securing threaded hole 23′ and the locating threaded hole 24′ in different diameters. Whereas an elastic lever is disposed to the tip of the elastic locating block and the support for the elastic lever must be provided on the top so to push a boring bar body 30′ to be tightly engaged with the adapter 20′; the engagement is prevented if the elastic locating block 241′ is mounted in the opposite direction.

Two limitation points 271′ and 272′ on the end surface of the adapter are comprised of insertion of two limiting pins. In the present invention, a fillister structure is provided in lieu of both limiting pins for easier production and reduced production cost while achieving the same purpose.

SUMMARY OF THE INVENTION

The primary purpose of the present invention, an improved construction of U.S. application Ser. No. 10/680,061 (patent pending) is to provide a high speed boring tool that is free of gyration balancing calibration due to changed bore size and contains a foolproof securing structure to inch the diameter of the bore by taking advantage of the eccentric principle.

To achieve the purpose, the boring tool of the present invention is essentially comprised of an adapter and a boring bar body; and the boring tool after the assembly of the boring bar body must be given gyration balancing for calibration so that the gyration balancing will not be changed in the interchange between two boring bar bodies in different bore sizes, thus to achieve the purpose of not requiring the gyration balancing calibration. A micro-eccentric bore is disposed on the front of the adapter to accommodate a pivoting shaft from the boring bar body. A V-shaped ring groove is disposed to the pivoting shaft. A securing and a locating threaded hole are provided on the adapter at where corresponding to the V-shaped ring groove. An eccentric locating recess is provided to each threaded hole. A securing screw is eccentrically disposed to a locating pin and an elastic locating screw to prevent confusion in the mounting of the locating screw and the limiting screw while allowing fast interchange between two different bore sizes. The elastic locating screw in the locating threaded hole is compressed by a screw for the boring bar body to upwardly push to achieve tight contact with the adapter. The boring bar body and the adapter are firmly secured to each other in radius and axially to provide excellent rigidity of the combination by tightening up a locating pin in the locating threaded hole and packing the screw.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an exploded view of the present invention.

FIG. 2 is a sectional view of the present invention as assembled.

FIG. 3 is a sectional view taken from section A-A of the present invention.

FIG. 4 is a perspective view of an adapter of the present invention.

FIG. 5 is a perspective view of a locating pin of the present invention.

FIG. 6 is a perspective view of an elastic locating pin of the present invention.

FIG. 7 is a magnified view of a local part showing the elastic locating pin is pushing a boring bar body of the present invention.

FIG. 8 is a perspective view of a boring bar body in diameter of 10 mm.

FIG. 9 is a perspective view of a boring bar body in diameter of 30 mm.

FIG. 10 is a perspective view of a boring bar body in diameter of 50 mm.

FIG. 11 is a schematic view showing that the position of the tip of the present invention is zeroed in.

FIG. 12 is a schematic view showing the maximal limitation of CW inching the bore at the position of the tip of the boring tool.

FIG. 13 is a schematic view showing the maximal limitation of CCW inching the bore at the position of the tip of the boring tool.

FIG. 14 is a schematic view showing CW inching limitation of the present invention.

FIG. 15 is a schematic view showing CCW inching limitation of the present invention.

FIG. 16 is an exploded view of a U.S. application Ser. No. 10/680,061 of the same applicant of the present invention.

FIG. 17 is a sectional view of an assembly of the U.S. application Ser. No. 10/680,061 of the same applicant of the present invention.

FIG. 18 is a sectional view showing the combination of an adapter and a boring bar body are respectively secured by a securing screw and a locating screw of the U.S. application Ser. No. 10/680,061 of the same applicant of the present invention.

FIG. 19 is a layout of an adjustable boring tool of the prior art.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring to FIGS. 1, 2, 3, and 5, the present invention is essentially includes an adapter 20 and a boring bar body 30. Wherein, one end of the adapter 20 is related to a tapering spindle 21 to be pivoted to a main shaft of a tooling machine; and another end on its surface is disposed with a micro-eccentric bore 22. A securing threaded hole 23 is provided to the tapering spindle 21 by the micro-eccentric bore 22. One or multiple locating slide 232 is disposed eccentrically from the center of the securing threaded hole 23. The securing threaded hole 23 contains a locating pin 40 and a securing screw 231 is locked into the securing threaded hole 23. A locating threaded hole is disposed on the adapter at a proper angle father away from the securing threaded hole 23. One or multiple locating slide 242 is provided eccentrically from the center of the locating threaded hole 24. The locating threaded hole 24 contains an elastic locating pin 50 and secured with a locating screw 241. Gradations 251 as illustrated in FIG. 4 are provided on a pyramidal face 25 of the adapter 20, and a recess 270 at an inclination of approximately 270 degrees is disposed on the inner circumference of the pyramidal face 25. Both ends of the recess 270 define two limitation points.

The boring bar body 30 is disposed at its front end a tool rest to accommodate a disposable insert 32. Another end of the boring bar body 30 is disposed with a pivoting shaft 33 inserted into the micro-eccentric bore 22 of the boring bar body. A V-shape recess 34 is provided to the boring bar body 30 at where corresponding to the securing threaded hole 23 to accommodate an elastic locating pin 50. A limiting pin is inserted to the op of the boring bar body 30 at where corresponding to both limitation points 271, 272.

As illustrated in FIG. 5, the front face of the locating pin 40 is made in a concave with its circular curvature same as that of the pivoting shaft 33 of the boring bar body 30 so to allow the face of the locating pin 40 to merely match with the pivoting shaft 33. A pin hole 41 is provided on and penetrating through the locating pin 40 at where closer to its terminal and deviating from the central shaft of the locating pin 40 to receive a locating pin 42.

Now referring to FIG. 6, the elastic locating pin 50 has at its front end cut a slot to become an elastic arm 51 with its support located at its upper portion. A pin hone 52 penetrating the elastic locating pin 50 is provided on the side close to its terminal and deviating from its central shaft to receiver insertion of a locating pin 53.

Assurance of a consistent gyration balancing and maintaining it while replacing the boring bar body 30 to change the bore size are achieved by the following steps:

-   1. The mass of the boring bar body must be consistent: Whereas the     position of the tool rest 31 must be changed depending on the size     of the boring bar body 30; the larger the bore size is, the larger     and heavier the tool rest 31 in the case of those boring bar bodies     30 respectively in diameters of 10 mm, 30 mm, and 50 mm illustrated     in FIGS. 8, 9, and 10. The mass of each boring bar body 30 must be     the same for securing stability of the boring tool revolving at high     speed. Accordingly, both of the mass and shape of the boring bar     body 30 must be modified. For example, the boring shaft body 30 in a     diameter of 10 mm as illustrated in FIG. 8 will have its tool rest     31 in smaller size while the size of the portion between where above     the tool rest 31 and the pivoting shaft must be increased to     compensate the mass. As for the boring shaft body 30 in diameter of     30 mm illustrated in FIG. 9, both of the mass and the size of its     tool rest 31 are greater than those of that in diameter of 10 mm ,     therefore the size of the portion between where above the tool rest     31 and the pivoting shaft 33 is smaller and modification must be     made to its mass to be identical with that of the boring bar body 30     in diameter of 10 mm . The greatest size of the tool rest 31 is     found with the boring bar body 30 in diameter of 50 mm as     illustrated in FIG. 10, therefore, the size of the portion between     where above the tool rest 31 and the pivoting shaft 33 must be     reduced for the mass of each of those three boring bar bodies 30     respectively in diameters of 10 mm, 30 mm , and 50 mm becomes the     same. Accordingly, for any bore size applicable, the mass of the     boring bar body must be the same or falling within the allowance. -   2. Calibrating the boring bar body to coincide its centers of mass     and form: after having made sure that each boring bar body 30 of all     bore sizes is identical or falls within the allowance, calibrating     the boring bar body to coincide it centers of mass and form is     immediately followed so to prevent the boring bar body from     eccentric vibration when revolving at high speed (20000 rpm or     higher). Each bore size of the boring bar body must be calibrated to     coincide its centers of mass and form, and the calibration may be     made with CAD package software and a gyration balancing machine. The     completion of the calibration for the prototype gives the green     light to mass production of the boring bar body in consistent     gyration balancing. -   3. Calibration of gyration balancing for the Adapter and the Boring     Bar Body: When secured in the combination of the coring bar body 30     and the adapter by means of a securing system, gyration balancing     must be computed and calibrated once again due to the presence of     the micro-eccentric bore 22 and associate parts from the securing     system, and again, the calibration may be made with CAD package     software and the gyration balancing machine.

Therefore, upon the completion of the consistent mass and gyration balancing calibration for the boring tool as a whole in Step 3, the boring tool will maintain stable operation at high speed of revolution without shaking or bias. With the coincided centers of mass and form, the gyration balancing maintains consistent when turning the boring bar body 30 is used to fine-tune the bore size after the interchange between boring bar bodies 30 in various diameters. Therefore the boring process by yielding excessively high precision of the true circle for the resultant bore achieved by the boring tool revolving at high speed perfectly comply with the expectation of the user. More importantly, calibration of gyration balancing is not required while changing for another boring bar body 30 in different diameter. Saving the calibration is the most important and an unprecedented innovative design of the present invention to correct the flaw of making the gyration balancing calibration for the boring bar body whenever the bore size is inched.

On securing the combination of the adapter 20 and the boring bar body 30 as illustrated in FIGS. 2, 3, and 7, the elastic locating pin 50 gradually pack against the V-shaped ring groove 34 as the locating screw 241 drives in. As the locating screw 241 drives further, the elastic locating pin 50 is compressed to cause its elastic arm deformed and thus produce spring-loaded energy. The elastic arm with its support as the center creates compressed deformation and releases its spring-loaded energy for upward ejection with the support of the elastic arm as the center to push the boring bar body 30 to be tightly engaged with the adapter 20. In turn, the limiting screw 231 in the securing threaded hole pushes the locating pin 40 to pack against the boring bar body 30. Both of the locating pin 40 and the boring bar body 30 are tightly engaged to each other to form an integral part since the curvature of the concave on the front of the locating pin 40 is same as that of the boring bar body 30. Accordingly, the boring bar body 30 is firmly secured to the adapter 20 either in radius or axially (Z-axle) to form integral rigidity.

As illustrated in FIGS. 1, 2, 3 and 5, the present invention is easy for assembly and foolproof designed. Wherein, both terminals of the locating pin 40 and the elastic locating pin 50 are respectively and eccentrically disposed with a locating pin 42, 53. The securing threaded hole 23 and each of the locating threaded hole 24 on the adapter 20 is respectively disposed with a locating slide 232, 242 biased from the center of the threaded hole. The diameter of the securing threaded hole 23 is different from that of the locating threaded hole 24. Relatively, the diameter of the locating pin 40 is also different from that of and the elastic locating pin 50 to prevent the risk of improper mounting. Meanwhile, the design of the locating slides 232, 242 makes it impossible to inversely mount the elastic locating pin 50 (the support of the elastic arm 51 must be provided in the upper part to provide upward push). The double foolproof design prevents improper mounting or inverse mounting from failing the function of the securing system.

The inching limitation range of the bore size is described as follows:

-   1. Zero-in Position: as illustrated in FIG. 11, the zero-in position     relates to that for the zeroed in tip size of the tool. The     micro-eccentric bore 22 is deflected to the left side of the central     shaft, i.e., on the opposite side to the securing threaded hole 23     while the tip of the tool is located to the very north at 90-degree.     The range, r, between the location of the tip of the tool and the     revolving center O is the gyration radius. The bore tool illustrated     in FIG. 11 relates to one in diameter of 25 mm . Therefore, the     position of the tool tip is where the bore size is zeroed in. -   2. Maximal CW inching bore size: as illustrated in FIG. 12, the     position of the tool tip is turned counterclockwise for 90 degrees     to fall in the direction heading for where the micro-eccentric bore     22 is deflected. Therefore, the radius of the bore, R=Deflection     Amount e+Gyration radius, r1 of the boring bar body. Given with the     boring bar body in diameter of 25 mm of the preferred embodiment as     illustrated in FIG. 12, the deflection amount e is 0.1 mm; r1, 12.5     mm ; bore radius, R, 12.6 mm; and maximal bore size, 25.2 mm. -   3. Minimum CCW inching bore size: referring to FIG. 13, the position     of the tip of the bore tool is tuned clockwise to its east as     illustrated, i.e., in the direction deflected to 0 degree. Whereas     the center of the boring bar body 30 is located at where left to the     gyration center O (and that of the adapter 20). Therefore, the     radius of the bore R is reduced to equal to =Gyration radius, r1 of     the boring bar body—Deflection Amount e. For the preferred     embodiment illustrated in FIG. 13, the bore radius R=12.5     mm−0.1=12.4 mm , the bore size is 24.8 mm in diameter, i.e., 0.2 mm     reduced in CCW direction.

As described above, the present invention is highly innovative and practical since only a deflection amount, e, at 0.1 mm will forthwith increase or reduce 0.2 mm in CW or CCW direction of the inched bore size.

For the safety design of limitation points as illustrated in FIGS. 1, 2, the boring bar body 30 and the adapter 20 are secured to each other by respectively packing the locating pin 40 and the elastic locating pin 50 with the securing screw 231 and the locating screw 241. Saving the design of the limitation points, the insert 32 upon contacting a work piece will immediately stop gyration to force the boring bar body 30 displacement, thus the insert 32 will hit the work piece and break up if the operator forgets to secure the boring bar body 30 after the bore size is fine tuned. As illustrated in FIGS. 14 and 15, the gyration range of the limiting pin 35 is the same inching range for the boring tool. FIG. 14 shows the inching limitation in CW direction; and FIG. 15, in CCW direction. Once the boring tool increases or decreases its inching size respectively in CW or CCW direction, both limiting points 271, 272 of the recess 270 serve the safety points to limit the limiting pin 35. If after the inching, both of the securing screw 231 and the locating screw 241 are not secured as a result of act of omission and the insert 32 of the boring bar body 30 upon contacting the work piece causes the boring bar body 30 to stop gyration, the adapter maintaining its CW gyration will cause the CCW limiting point 271 to hit the limiting pin 35 as illustrated in FIG. 15, thus to drive synchronously the boring bar body 30 to gyrate. Meanwhile, as the adapter is gyrating, the boring bar body 30 has already inched in CCW direction and the location of the tip of the boring tool will be short of the size of the bore to prevent from hitting the insert 32. For example, if the bore size is 25.1 mm in diameter for the work piece, the hole on the work piece should processed to a range of ψ24.9˜ψ25 mm with the size of the tip of the boring tool for the insert 30 of the boring bar body 30 should be reduced to its minimum of ψ24.8 mm . The boring bar body 30 is synchronously driven by the limiting pin 35 linked to the limiting pin 271, and the position of the tip of the insert is maintained at its position when the minimum cutting size takes place. Consequently, the insert 32 will not hit the work piece so to protect the safety of the insert 32.

The present invention by providing a boring tool that does not require further gyration balancing calibration upon interchanging between two different bore sizes; that is designed with limiting points to protects the insert from hitting the work piece in case of failure to lock the securing screw due to act of omission; that is reliably secured in both axial and radius directions by means of a locating pin and an elastic locating pin in conjunctions with screws; that is capable of withstanding vibration and prevents from loosening; and that is foolproof to prevent improper mounting is innovative, advanced, and giving powerful competition strength in the trade; therefore, this application for a patent is duly filed accordingly. 

1. A manufacturing process of a high speed boring tool free of gyration balancing calibration and allowing fast interchange of different bore sizes a. Setting up consistent mass of multiple boring bar bodies: the mass of each of all boring bar bodies for different bore sizes must be the same; and multiple boring bar bodies in different bore size must be modified to share consistent mass and form or falling within a given allowance; b. Calibrating to coincide both centers of mass and form of the boring bar body: the center of mass and the center of form of the boring bar body must be calibrated for both to coincide with each other thus to prevent producing eccentric vibration when the boring bar body is gyrating at high speed; and c. Calibration of gyration balancing performed for the assembly of the boring bar body and the adapter: calibration of gyration balancing is provided to both of the boring bar body and the adapter when secured to each other by means of a securing system.
 2. A high speed boring tool free of gyration balancing calibration and allowing fast interchange of different bore sizes is comprised of an adapter, having one end disposed as a BT40 tapering spindle to be pivoted to a main shaft of a tooling machine, another end on its surface disposed a micro-eccentric bore, on an axle of the micro-eccentric bore being disposed with a securing threaded hole, one or multiple locating slide biased from the center of the threaded hole being disposed to the securing threaded hole, a locating hole being disposed on the adapter at a proper angle biased from the securing threaded hole, one or multiple locating slide biased from the center of the threaded hole being disposed to the locating threaded hole, a recess being provided at where appropriately on the end surface of the adapter; each of two limiting ends of the recess defining a limitation point; a boring bar body, having a tool rest disposed at its front end to fasten an insert, another end being connected to a pivoting shaft, the pivoting shaft being received in the micro-eccentric bore; a V-shaped ring groove being provided in relation to the securing threaded hole; and a limiting pin being inserted into the top of the boring bar body at where corresponding to the axle of the limitation point; a locating pin being accommodated in the securing threaded hole; a securing screw, fastened to the securing threaded hole on the adapter; an elastic locating pin accommodated in the locating threaded hole to push the boring bar body up and front to hold tightly against the adapter; and a locating screw fastened to the locating threaded hole to pack against the elastic locating pin to secure the boring bar body; and
 3. The boring tool of claim 2, wherein the front end of the locating-pin is made in a concave.
 4. The boring tool of claim 2, wherein a pin hole penetrating through and biased from the central shaft is provided on the side of the locating pin at where close to its terminal to accommodate a locating pin.
 5. The boring tool of claim 2 wherein a slot is cut on the front end of the elastic locating pin to define an elastic arm.
 6. The boring tool of claim 2, wherein a pin hole penetrating through and biased from the central shaft is provided on the side of the elastic locating pin at where close to its terminal to accommodate a locating pin. 